CN205958833U - Optical imaging device and spotlight ware thereof - Google Patents
Optical imaging device and spotlight ware thereof Download PDFInfo
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- CN205958833U CN205958833U CN201521031140.1U CN201521031140U CN205958833U CN 205958833 U CN205958833 U CN 205958833U CN 201521031140 U CN201521031140 U CN 201521031140U CN 205958833 U CN205958833 U CN 205958833U
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- Photometry And Measurement Of Optical Pulse Characteristics (AREA)
Abstract
The utility model provides an optical imaging device, it includes this spotlight ware, and wherein this spotlight vessel shape becomes a spotlight light path, and wherein this spotlight ware is set up reverberation to this spotlight light path that can assemble the formation of image object, an optical sensor, wherein this optical sensor is set up in this spotlight light path, and wherein this optical sensor is used for the response to be assembled to the reverberation and the corresponding smooth sensing signal of formation of this spotlight light path, with a signal processing module, wherein this signal processing module can be connected with this optical sensor with switching on to set up the smooth sensing signal that can receive this optical sensor and generate.
Description
Technical field
This utility model is related to optical imaging apparatus, more particularly, to a kind of condenser for optical imagery, and wherein this gathers
Light device can converge the reflected light of the imaging object in polarizers of big angle scope, so that the reflected light of the imaging object in polarizers of big angle scope
By single sensor sensing.
Background technology
With scientific and technical development, optical imaging apparatus (device) are by exploitation in succession, such as photographing unit, shooting
Machine etc. is all in succession developed and is updated.But existing optical imaging apparatus, there are following problems more:First, existing optics
The imaging of imaging device is limited by imaging angle (or visual angle) or imaging direction, and it is only capable of making in certain direction or effectively regards
Subject (or imaging object) imaging in angle range, and the object of optical imaging apparatus both sides and equipment back side cannot be become
Picture and shown.In other words, the imaging of existing majority optical imaging apparatus, because of the restriction at its visual angle, and leads to it to be only capable of making
Image objects in its effective angular field of view.Therefore, existing optical imaging apparatus are when imaging to imaging object, if should
Optical imaging apparatus need to make all objects in certain space be imaged, then need this optical imaging apparatus to be placed in this space
Certain one end, and so that all imaging objects is in effective visual angle of this optical imaging apparatus.But, when this optical imaging apparatus
When being placed in certain one end in this space, necessarily lead to the distance between different imaging objects and this optical imaging apparatus different,
Apart from the more remote imaging object of this optical imaging apparatus, its imaging is more unintelligible.And due to the multiple imaging things in this space
Body is all imaged in same two-dimensional picture, and the imaging that this is easily caused imaging object deforms, and deviates this optical device
The axis at visual angle is more remote and apart from the more remote imaging object of this optical imaging apparatus, and its imaging more easily obscures and deforms.Cause
This, even if certain one end this optical imaging apparatus being arranged in this space, nor necessarily guarantee that being in this optical imagery sets
All imaging objects of standby dead ahead realize blur-free imaging.Only in effective visual angle of this optical imaging apparatus and with this optics
When the distance of imaging device is suitable, just can ensure that all imaging objects realize blur-free imaging.On the other hand, due to this optical imagery
Effective visual angle of equipment is an angular range, in this different azimuth at effective visual angle that can lead to be in this optical imaging apparatus
Imaging object image quality, especially definition, would also vary from.Therefore, existing optical device is being implemented as picture
When, the image quality being in the imaging object of diverse location does not have homogeneous (or identical) property, and this can be to user (or image-watching
Person) bring the experience of bad luck in some instances it may even be possible to image-watching person can be allowed to feel dizziness and nausea.Secondly, existing optical imaging apparatus
Wide-angle imaging to be realized, if the angular range size of wide-angle exceedes effective visual angle of its photographic head, this optical imagery
Equipment is accomplished by multiple photographic head or sensor, and multiple angular ranges are shot, then by splicing means by obtain
Repeatedly imaging results are stitched together, to obtain wide-angle, such as 360 degree look around in the range of all imaging objects image.But
Be this shearing after splice the image obtaining again, its imaging effect is typically poor.Because whole image is multiple images splicing shape
Become, in stitching portion, even blank can be there is carry out softening process through the algorithm optimizing, the image of stitching portion also can be with
Natural image has obvious difference.In addition, the splicing of two images needs this two images all to be sheared in position, but
Determine that the difficulty of the stitching position of two images is very big simultaneously.Again, the maximum visual angle of existing pick-up lenss is certain, because
This, existing optical imaging apparatus need multiple photographic head and sensor to realize Wide-angle imaging, and each photographic head or sensing
Device needs to realize synchronous working, and this leads to whole optical imaging apparatus complex structure, and the excessive inconvenience of volume uses and production cost
High.Finally, realizing Wide-angle imaging using multiple photographic head or sensor needs multiple image mosaic, leads to actual at it
During imaging, the processor (if any) of this optical imaging apparatus needs the more time to complete multiple calculation procedures and realization
The splicing of whole image, this can lead to it cannot instantaneous imaging and be not easy to be applied to long-range real-time communication.In addition, existing optics
Imaging device using multiple photographic head or sensor when realizing Wide-angle imaging it is also possible to the synchronization in signal processing can be run into
Problem.Usually, optical imagery to be realized typically requires the synergism of multiple functional parts.When using multiple photographic head or biography
When realizing Wide-angle imaging, different photographic head or sensor are imaged sensor respectively, then these photographic head or sensor correspond to
Different heterogeneity (or identical) property of functional part of other and difference all can be led to the asynchronism of signal-data processing
Imaging, this also can affect the image quality of this optical imaging apparatus.
Utility model content
The purpose of this utility model is to provide a kind of optical imaging device, wherein the condenser energy of this optical imaging device
Enough convergence is located at wide-angle, the reflected light of the imaging object in even 360 degree angular ranges, so that in polarizers of big angle scope
The reflected light of all imaging objects all can be by single sensor sensing.
The purpose of this utility model is to provide a kind of optical imaging device, wherein the condenser quilt of this optical imaging device
Setting has a large viewing and can converge the reflected light of the imaging object in this condenser angular field of view, so that greatly
The reflected light of all imaging objects in angular range is sensed and synchronous imaging by single sensor simultaneously.
The purpose of this utility model is to provide a kind of optical imaging device, wherein the condenser shape of this optical imaging device
Become first reflected light path and second reflected light path, wherein this second reflected light path is formed at this first reflected light path
Inner side.
The purpose of this utility model is to provide a kind of optical imaging device, wherein the condenser shape of this optical imaging device
Become first reflected light path and second reflected light path, the reflected light of the imaging object in wherein different angles is reflected into
After entering this first reflected light path, this reflected light of this imaging object can be again reflected and enter this second reflected light path.
The purpose of this utility model is to provide a kind of optical imaging device, wherein the condenser shape of this optical imaging device
Become first reflected light path and second reflected light path, the reflected light of the imaging object in wherein different angles is reflected into
After entering this first reflected light path, the reflected light of the imaging object in different angles can be again reflected and converge entrance this second
Reflected light path, so that the optical pickocff that the reflected light of all imaging objects all can be arranged on this second reflected light path by
Sensing.
The purpose of this utility model is to provide a kind of optical imaging device, wherein the condenser shape of this optical imaging device
Become first reflected light path and second reflected light path, wherein this second reflected light path forms a sensing light path, wherein
This optical pickocff is arranged on this sensing light path, so that the reflected light of all imaging objects all can be sensed.
The purpose of this utility model is to provide a kind of optical imaging device, wherein the condenser shape of this optical imaging device
Become first reflected light path and second reflected light path, this sensing light path that wherein this second reflected light path is formed is hidden
Be arranged on this optical imaging device condenser this first reflecting element formed photosensitive interior.
The purpose of this utility model is to provide a kind of optical imaging device, and the wherein condenser of this optical imaging device should
The outer surface of the first reflecting element is provided with one layer of reflecting layer, to improve the light reflection efficiency of this first reflecting surface.
The purpose of this utility model is to provide a kind of optical imaging device, and the wherein condenser of this optical imaging device should
First reflecting element includes one layer of reflecting layer, and wherein this reflecting layer is made up of oxidation-resistant material, to prevent this reflecting layer from being formed
First reflecting surface is by the service life of Quick Oxidation and this first reflecting element of raising.
The purpose of this utility model is to provide a kind of optical imaging device, wherein the condenser of this optical imaging device
This cover body allows the reflected light of imaging object to pass through and keep this first reflecting element and second reflection of this optical imaging device
Element is set with practising physiognomy opposite.Preferably, this cover body is made of clear material.
The purpose of this utility model is to provide a kind of optical imaging device, wherein the condenser of this optical imaging device
This cover body is sealingly disposed between this first reflecting element and this second reflecting element, and this first reflecting element, this second
Reflecting element and this cover body form an optically focused room, and wherein this optically focused room is charged noble gases or is kept vacuum, to prevent
The anti oxidation layer of the outer surface of this first reflecting element service life that is oxidized and improving this first reflecting element.
The purpose of this utility model is to provide a kind of optical imaging device, wherein the condenser of this optical imaging device
This cover body is arranged between this first reflecting element and this second reflecting element, and respectively with this first reflecting element and this second
Reflecting element is integrally formed, so that the optically focused room that this first reflecting element, this second reflecting element and this cover body are formed can be protected
Hold and be isolated with extraneous air so that this optically focused room can be charged noble gases or be kept vacuum, with prevent this first
The anti oxidation layer of the outer surface of reflecting element service life that is oxidized and improving this first reflecting element.
The purpose of this utility model is to provide a kind of optical imaging device, the wherein signal processing of this optical imaging device
Module can receive the sensor detection of this optical imaging device or the optical signal that senses this optical signal is carried out process and
Imaging.
The purpose of this utility model is to provide a kind of optical imaging device, wherein this condenser of this optical imaging device
The second reflecting surface coaxial with the light entrance of this sensitizing chamber.
The purpose of this utility model is to provide a kind of optical imaging device, the wherein optical sensing of this optical imaging device
Device is hidden in this sensitizing chamber, and this second reflecting surface of this optical imaging device is hidden in a reflection room.
The purpose of this utility model is to further provide for a kind of condenser for optical imaging device, wherein this optically focused
Device can synchronously and similarly converge positioned at wide-angle, the reflected light of the imaging object in even 360 degree angular ranges, with
The reflected light making all imaging objects in polarizers of big angle scope all can be by single sensor sensing.
The purpose of this utility model is to further provide for a kind of condenser for optical imaging device, wherein this optically focused
Device can converge the reflected light of the imaging object in polarizers of big angle scope, so that all imaging objects in polarizers of big angle scope
Reflected light is sensed by single sensor simultaneously, can enable all imaging objects by synchronous imaging.
The purpose of this utility model is to further provide for a kind of condenser for optical imaging device, wherein this optically focused
Device forms first reflected light path and second reflected light path, and wherein this second reflected light path is formed at this first reflected light
The inner side on road.
The purpose of this utility model is to further provide for a kind of condenser for optical imaging device, wherein this optically focused
Device forms first reflected light path and second reflected light path, and the reflected light of the imaging object in wherein different angles is anti-
After injecting this first reflected light path, this reflected light of this imaging object can be again reflected and enter this second reflected light
Road.
The purpose of this utility model is to further provide for a kind of condenser for optical imaging device, wherein this optically focused
Device forms first reflected light path and second reflected light path, and the reflected light of the imaging object in wherein different angles is anti-
After injecting this first reflected light path, the reflected light of the imaging object in different angles can be again reflected and be accumulated entrance
This second reflected light path, so that the reflected light of all imaging objects all can be arranged on the single optics of this second reflected light path
Sensor sensing.
The purpose of this utility model is to further provide for a kind of condenser for optical imaging device, wherein this optically focused
First reflecting element of device is equipped with one layer of reflecting layer, to improve the light reflection efficiency of this first reflecting surface.
The purpose of this utility model is to further provide for a kind of condenser for optical imaging device, wherein this optically focused
First reflecting element of device is equipped with one layer of reflecting layer, and wherein this reflecting layer is made up of oxidation-resistant material, to prevent this reflection
The first reflecting surface that layer is formed is by the service life of Quick Oxidation and this first reflecting element of raising.
The purpose of this utility model is to further provide for a kind of condenser for optical imaging device, wherein this optically focused
This cover body of device allows the reflected light of imaging object to pass through, and keeps this first reflecting element and second reflector of this condenser
Part is set with practising physiognomy opposite.Preferably, this cover body is made up of high light transmissive material.
The purpose of this utility model is to further provide for a kind of condenser for optical imaging device, wherein this optically focused
This cover body of device is sealingly disposed between this first reflecting element and this second reflecting element, and this first reflecting element, should
Second reflecting element and this cover body form an optically focused room, and wherein this optically focused room is charged noble gases or is kept vacuum, with
Prevent the anti oxidation layer service life that is oxidized and improving this first reflecting element of the outer surface of this first reflecting element.
The purpose of this utility model is to further provide for a kind of condenser for optical imaging device, wherein this optically focused
This cover body of device is arranged between this first reflecting element and this second reflecting element, and respectively with this first reflecting element and should
Second reflecting element is integrally formed, so that the optically focused room that this first reflecting element, this second reflecting element and this cover body are formed can
It is kept and is isolated with extraneous air, so that this optically focused room can be charged noble gases or be kept vacuum, to prevent this
The anti oxidation layer of the outer surface of the first reflecting element service life that is oxidized and improving this first reflecting element.
The purpose of this utility model is to further provide for a kind of condenser for optical imaging device, wherein this optically focused
This second reflecting surface of device is coaxial with the light entrance of this sensitizing chamber.
The purpose of this utility model is to further provide for a kind of condenser for optical imaging device, wherein this optically focused
This first reflecting surface of device is convex curved reflecting surfaces, and this second reflecting surface is a plane reflection face.
The purpose of this utility model is to further provide for a kind of condenser for optical imaging device, wherein this optically focused
This first reflecting surface of device and the surface of this second reflecting surface are smooth surface.
The purpose of this utility model is to further provide for a kind of condenser for optical imaging device, wherein this optically focused
Device arranges and is formed with being integrally formed.
The purpose of this utility model is to further provide for a kind of condenser for optical imaging device, wherein this optically focused
First reflecting surface of device and the second reflecting surface are arranged with being faced each other face.
The purpose of this utility model is to provide a kind of optical imaging device, wherein this second reflecting surface quilt of this condenser
It is hidden in a reflection room.
Other purpose of the present utility model and feature are fully demonstrated by following detailed descriptions and can be passed through appended
Specially the means pointed out in claim and the combination of device are achieved.
According to this utility model, it is capable of this utility model optical imaging device of object defined above and other purposes and advantage
Including:
One this condenser, wherein this condenser have an axis and form an optically focused light path, wherein this optically focused
The visual angle of device is set and is formed around this axis, so that this condenser is set the one-tenth that can converge this condenser angular field of view
As the reflected light of object is to this optically focused light path;
One optical pickocff, wherein this optical pickocff are arranged on this optically focused light path, wherein this optical pickocff quilt
Setting can sense the reflected light being accumulated to this optically focused light path and the corresponding light sensation induction signal of generation;With
One signal processing module, wherein this signal processing module can be connected with this optical pickocff with being energized, wherein
This signal processing module is set this light sensation induction signal that can receive the generation of this optical pickocff.
This utility model further provides for a kind of condenser, and wherein this condenser has an axis and formation one gathers
The visual angle of light light path, wherein this condenser is set and is formed around this axis, so that this condenser is set can converge this
The reflected light of the imaging object of condenser angular field of view to this optically focused light path, wherein this condenser formed first reflecting surface and
One the second reflecting surface, wherein this first reflecting surface and the second reflecting surface are separated by be arranged with turning up the soil and practise physiognomy opposite, wherein should
First reflecting surface and this second reflecting surface form first reflected light path and second reflected light path, wherein this first reflection
Light path is formed between this first reflecting surface and this second reflecting surface, and this second reflected light path is formed at this first reflected light path
The reflected light back of imaging object can be entered this first reflected light path by inner side, wherein this first reflecting surface, and in imaging thing
The reflected light of body is entered after this first reflected light path by this first reflective surface, the reflected light of imaging object can by this second
Reflecting surface secondary reflection and this second reflected light path of entrance again.
Therefore, as described above, the optical imaging device that this utility model is somebody's turn to do has in following beneficial effects at least within
One of:
1st, the condenser of this utility model optical imaging device can be used for Wide-angle imaging it is also possible to be used for smaller angle model
Surround picture;
2nd, the condenser of this utility model optical imaging device can synchronously and equally (or similarly) by wide-angle
The reflected light of imaging object converges to this second reflected light path and so that it is sensed by single optical pickocff;
3rd, the second reflecting surface of the condenser of this utility model optical imaging device and optical pickocff are arranged with being hidden,
Thus the interference imaging of unexpected reflected light can be reduced as far as possible;
4th, the first reflecting surface of the condenser of this utility model optical imaging device is formed by antioxidant, and this improves
The service life of this condenser;
5th, the optically focused room of the condenser of this utility model optical imaging device is charged inert protective gas or is kept true
Sky, this first reflecting surface that can protect condenser further and the service life improving this condenser.
By the understanding to subsequent description and accompanying drawing, the further purpose of this utility model and advantage will be able to abundant body
Existing.
These and other objects of the present utility model, feature and advantage, by following detailed descriptions, accompanying drawing and right will
Try to achieve to fully demonstrate.
Brief description
Fig. 1 is the axonometric chart of the optical imaging device according to this utility model preferred embodiment, and this figure is shown that this practicality
The condenser of novel optical imaging device.
Fig. 2 is the explosive view of the condenser of the above-mentioned optical imaging device according to this utility model preferred embodiment.
Fig. 3 is the first reflecting element of the condenser of the above-mentioned optical imaging device according to this utility model preferred embodiment
Axonometric chart.
Fig. 4 is the second reflecting element of the condenser of the above-mentioned optical imaging device according to this utility model preferred embodiment
Upward view.
Fig. 5 is the solid of the supporting part of condenser of the above-mentioned optical imaging device according to this utility model preferred embodiment
Figure.
Fig. 6 is the axonometric chart of the cover body of condenser of the above-mentioned optical imaging device according to this utility model preferred embodiment.
Fig. 7 A is the sectional view of the condenser of the above-mentioned optical imaging device according to this utility model preferred embodiment, and this figure shows
Show that the reflected light of imaging object is accumulated after sequentially passing through the first reflected light path of optical imaging device and the second reflected light path.
Fig. 7 B is the sectional view of the above-mentioned optical imaging device according to this utility model preferred embodiment, the figure illustrates imaging
The reflected light of object is accumulated and by this light after sequentially passing through the first reflected light path of optical imaging device and the second reflected light path
Learn the sensor sensing of imaging device.
Fig. 8 A is the optional enforcement of one kind of the condenser of the above-mentioned optical imaging device according to this utility model preferred embodiment
Sectional view.
Fig. 8 B is this optional enforcement of the condenser of the above-mentioned optical imaging device according to this utility model preferred embodiment
The axonometric chart of this second reflecting element.
Specific embodiment
Hereinafter describe for disclosing this utility model so that those skilled in the art are capable of this utility model.Hereinafter retouch
Preferred embodiment in stating is only used as illustrating, it may occur to persons skilled in the art that other obvious modifications.Retouch following
The ultimate principle of the present utility model defining in stating can apply to other embodiments, deformation program, improvement project, etc. Tongfang
Case and the other technologies scheme without departing from spirit and scope of the present utility model.
With reference to Fig. 1 to Fig. 7 B of this utility model accompanying drawing, according to the optical imaging device quilt of this utility model preferred embodiment
Illustrate, wherein this optical imaging device includes 10, optical pickocff 20 of a condenser and a signal processing module 30,
Wherein this condenser 10 is set in the wide-angle angular field of view that can converge this condenser 10, in the range of even 360 degree
The reflected light of imaging object, allows it to be sensed by single optical pickocff 20, this optical pickocff 20 and this signal processing
Module 30 can be connected and the reflected light of imaging object and generation that can sense this condenser 10 converge is set with being energized
Corresponding light sensation induction signal, this signal processing module 30 can receive the light sensation induction signal of this optical pickocff 20 and to this light sensation
Induction signal is processed and is obtained imaging signal.It will be understood by those skilled in the art that this imaging signal can be transferred to display
Equipment and shown equipment are shown as image or video.Preferably, this condenser 10 is provided having a wide-angle visual angle.More
Preferably, this condenser 10 has an axis 103, and the visual angle of wherein this condenser 10 is set around this axis 103,
So that this condenser 10 has a wide-angle visual angle.
As shown in Fig. 7 A and Fig. 7 B of accompanying drawing, according to this optically focused of this optical imaging device of this utility model preferred embodiment
Device 10 forms an optically focused light path 1001, and wherein this condenser 10 is set the reflected light that can converge imaging object to this optically focused
Light path 1001.Preferably, this optical pickocff 20 is arranged on this optically focused light path 1001.
As shown in Fig. 7 A and Fig. 7 B of accompanying drawing, according to this optically focused of this optical imaging device of this utility model preferred embodiment
Device 10 has first reflecting surface 101 and second reflecting surface 102, wherein this first reflecting surface 101 and the second reflecting surface
102 are arranged with being practised physiognomy opposite, and wherein this first reflecting surface 101 and this second reflecting surface 102 form first reflected light path
110 and second reflected light path 120, wherein this first reflected light path 110 is formed at this first reflecting surface 101 and this is second anti-
Penetrate between face 102, this second reflected light path 120 is formed at the inner side of this first reflected light path 110, wherein this first reflecting surface
The reflected light back of imaging object can be entered this first reflected light path 110 by 101, and imaging object reflected light by this
After one reflecting surface 101 is reflected into this first reflected light path 110, the reflected light of imaging object can be by this second reflecting surface 102
Secondary reflection and this second reflected light path 120 of entrance again.
As shown in Fig. 7 A and Fig. 7 B of accompanying drawing, according to this optically focused of this optical imaging device of this utility model preferred embodiment
Device 10 includes first reflecting element 11 and second reflecting element 12, wherein this first reflecting element 11 formed this first
Reflecting surface 101, this second reflecting element 12 forms this second reflecting surface 102, wherein this first reflecting element 11 and this is second anti-
Penetrate element 12 and be separated by and arrange with turning up the soil dough-making powder opposite, so that this this first reflecting surface 101 and this second reflecting surface 102 being capable of shapes
Become first reflected light path 110 and second reflected light path 120.In other words, this first reflected light path 110 is formed at this
Between first reflecting element 11 and the second reflecting element 12, this second reflected light path 120 is formed at this first reflected light path 110
This first reflecting surface 101 of inner side, wherein this first reflecting element 11 allows in the wide-angle angular field of view of this condenser 10
The reflected light of imaging object be mapped to this first reflecting element 11 this first reflecting surface 101 and can be by this first reflecting element 11
This first reflecting surface 101 be reflected into the first reflected light path 110, the wherein imaging object in the different angles of this condenser 10
Reflected light be reflected into after this first reflected light path 110 by this first reflecting surface 101 of this first reflecting element 11, this imaging
This reflected light of object can be by this second reflecting surface 102 secondary reflection and this second reflected light path 120 of entrance again.
It will be understood by those skilled in the art that because this second reflected light path 120 is formed at this first reflected light path 110
Inner side, therefore, this second reflected light path 120 can converge the reflected light of the imaging object of this first reflecting surface 101 reflection.Change sentence
Talk about, this second reflected light path 120 forms an optically focused light path 1001, so that this condenser 10 of this optical imaging device
Can converge in the wide-angle angular field of view of this condenser 10, the imaging object in even 360 degree angular ranges anti-
Penetrate light, so that the reflected light of all imaging objects in the wide-angle angular field of view of this condenser 10 all can be arranged on this
The single optical pickocff 20 of the second reflected light path 120 (or perhaps this optically focused light path 1001) senses.Therefore, this second reflection
Light path 120 formed this optically focused light path 1001, imaging object there is the reflected light of suitable incident angle by this first reflecting element
After 11 this first reflecting surface 101 optionally reflects and enters this first reflected light path 110, by this second reflecting element 12
This second reflecting surface 102 secondary reflection again, thus being accumulated and entering this second reflected light path 120.Further, since this optical imagery
The convergence of this reflected light to imaging object for the condenser 10 of device is that synchronization is carried out in real time, and therefore, this condenser 10 can
Converge the reflected light of the imaging object being located in the wide-angle angular field of view of this condenser 10, and make the wide-angle of this condenser 10
The reflected light of all imaging objects in angular field of view is by the synchronous sensing of single optical pickocff 20.
As shown in Fig. 7 A and Fig. 7 B of accompanying drawing, according to this optics of this optical imaging device of this utility model preferred embodiment
Sensor 20 is arranged on this second reflected light path 120, or is set just to this second reflected light path 120, therefore, works as difference
After the reflected light of the imaging object in angle is reflected into this first reflected light path 110, imaging object in different angles
Reflected light can be again reflected and assemble this second reflected light path 120 of entrance, so that the wide-angle visual angle model of this condenser 10
The spectral sensor 20 that the reflected light of all imaging objects in enclosing all can be arranged on this second reflected light path 120 is felt
Should.
It should be noted that wide-angle herein refers to visual angle or angle in a big way, this condenser wherein herein
10 wide-angle angular field of view refers to the angular field of view not less than 20 degree.Preferably, wide-angle herein refer to not little
In 60 degree of angular field of view.It is highly preferred that wide-angle herein refers to 360 degree of angular field of view.People in the art can
To understand, when the visual angle angular range of this condenser 10 is 360 degree, condenser looked around by this condenser 10 actually,
This condenser 10 allows all imagings in this condenser 10 wide-angle angular field of view, in even 360 degree angulars field of view
The reflected light of object all can synchronously and similarly be reflected by this condenser 10 and converge.Further, since this condenser 10 para-position
It is homogeneous (or identical), therefore, this optical imaging device in the reflection of the reflected light of the imaging object of all angles with convergence
The imaging being pointed to the imaging object of all angles is also homogeneous (or identical), and this can at utmost reduce due to imaging object
The imaging heterogeneity (or identical) leading in different angles and the sight improving user (referred to herein as watching the people of image)
See experience.In other words, regard at each according to the structure of the condenser 10 of the optical imaging device of this utility model preferred embodiment
It is the identical with holding of homogeneous (or identical) in the angle of angle, therefore, same object, if this condenser 10 of this object distance
Distance keeps constant, then in each visual angle angle of the same level height of this condenser 10, imaging keeps this object
Constant.As shown in Fig. 2 and Fig. 3 of accompanying drawing, this first reflecting surface 101 is preferably convex curved reflecting surfaces, this second reflecting surface 102
A preferably plane reflection face.Therefore, this first reflecting surface 101 of this first reflecting element 11 can be a convex surface minute surface,
To form this convex curved reflecting surfaces;This second reflecting surface 102 of this second reflecting element 12 can be a flat mirror, is somebody's turn to do with being formed
Plane reflection face.It will be understood by those skilled in the art that this first reflecting surface 101 and this equal smooth surface of the second reflecting surface 102,
To improve the reflection efficiency of this first reflecting surface 101 and this second reflecting surface 102.Preferably, this first reflecting surface 101 and this
The shape of two reflectings surface 102 is mutually adapted.It is highly preferred that this first reflecting surface 101 be shaped as circular arc, this second reflecting surface
102 generally circular in shape, as shown in Fig. 5 of accompanying drawing.Most preferably, this first reflecting surface 101 of this first reflecting element 11
Projection radius is R1, and the projection radius of this second reflecting surface 102 of this second reflecting element 12 is R2, wherein this first reflecting surface
101 projection radius R1 is more than the projection radius R2 of this second reflecting surface 102.
As shown in Fig. 2 and Fig. 3 of accompanying drawing, this first reflecting surface 101 of this first reflecting element 11 is further arranged certainly
Upper and downly and outwardly extend.Preferably, this first reflecting surface 101 of this first reflecting element 11 is from top to down and outwards
Ground is continuous to be extended, to form a continuous convex surface.It is highly preferred that this first reflecting surface 101 of this first reflecting element 11
Horizontal plane centrosymmetry.Most preferably, this first reflecting surface 101 of this first reflecting element 11 has a preset curvature, and
The curvature of each several part of this first reflecting surface 101 of this first reflecting element 11 keeps constant.
As shown in Fig. 2 and Fig. 3 of accompanying drawing, the formation further of this first reflecting element 11 of this condenser 10 one with should
The sensitizing chamber 1100 that second reflected light path 120 is connected, wherein this second reflected light path 120 (or this optically focused light path 1001) is at this
Sensitizing chamber 1100 forms a sensing light path 1201, and wherein this optical pickocff 20 is arranged on this sensing light path 1201, thus
This optical pickocff 20 is made to be arranged on this sensitizing chamber 1100 of this first reflecting element 11 with being hidden.Preferably, this is photosensitive
Room 1100 has a light entrance 1101, wherein this light entrance 1101 be arranged on this second reflected light path 120 (or just to this second
Reflected light path 120) so that the reflected light passing through this second reflected light path 120 can pass through the entrance of this light entrance 1101, and this is photosensitive
Room 1100.It is highly preferred that this second reflecting surface 102 of this second reflecting element 12 of this condenser 10 and this sensitizing chamber 1100
This light entrance 1101 is coaxial.Most preferably, this first reflecting element 11 of this condenser 10 forms this light entrance 1101.
As shown in Fig. 7 A and Fig. 7 B of accompanying drawing, according to this optically focused of this optical imaging device of this utility model preferred embodiment
This first reflecting element 11 of device 10 further includes one first reflection body 111 and first reflecting layer 112, wherein should
First reflection body 111 has a lateral surface 1110, and this first reflecting layer 112 of wherein this first reflection body 111 is set
Put this lateral surface 1110 of this first reflection body 111 in this first reflecting element 11, and form this first reflecting element 11
This first reflecting surface 101.Preferably, this first reflecting layer 112 is by the metal material with good light reflection efficiency, such as aluminum,
Silver-colored or golden etc. make, to improve the light reflection efficiency of this first reflecting surface 101 of this first reflecting element 11 of this condenser 10.
It is highly preferred that this first reflecting layer 112 is the coat of metal with good oxidation resistance, such as electroplating aluminum coating.Alternatively, this gathers
This first reflecting layer 112 of this first reflecting element 11 of light device 10 be sprayed-on being arranged on this first reflecting element 11 this first
This lateral surface 1110 of reflection body 111.Alternatively, this first reflecting layer 112 is coated over being somebody's turn to do of this first reflecting element 11
This lateral surface 1110 of first reflection body 111.Alternatively, this first reflecting layer 112 can be by having good light reflection efficiency
Nonmetallic materials are made.It will be understood by those skilled in the art that when this first reflecting layer 112 is arranged on this first reflecting element
During 11 this lateral surface 1110 of this first reflection body 111, this first reflecting layer 112 can reduce or even stop imaging object
Reflected light pass through this first reflecting surface 101 and be refracted and enter this sensitizing chamber 1100 that this first reflecting element 11 is formed, and
This optical pickocff 20 being arranged in this sensitizing chamber 1100 senses.In other words, this first reflecting layer 112 is preferably by impermeable
Luminescent material is made.
As shown in Fig. 2 to Fig. 5 of accompanying drawing, according to this condenser of this optical imaging device of this utility model preferred embodiment
10 this second reflecting element 12 further includes a reflecting part 121 and a maintaining part 122, wherein this reflecting part 121 shape
Become this second reflecting surface 102, wherein this maintaining part 122 stretches out from this reflecting part 121 of this second reflecting element 12, wherein
This maintaining part 122 is set and this second reflecting element 12 can be kept to be in an appropriate location, so that this second reflecting element
12 this second reflecting surface 102 is kept towards this first reflecting surface 101.
As shown in Fig. 2 to Fig. 5 of accompanying drawing, this maintaining part 122 of this second reflecting element 12 of this condenser 10 is further
Form a reflection room 1220, this reflecting part 121 of wherein this second reflecting element 12 is arranged in this reflection room 1220, from
And make this second reflecting surface 102 of this second reflecting element 12 be arranged on this reflection room 1220 with being hidden, to subtract as far as possible
Light outside few reflected light of imaging object being reflected by this first reflecting element 11 is reflected and entered by this second reflecting surface 102
Enter this second reflected light path 120.
As shown in Fig. 2 to Fig. 5 of accompanying drawing, this maintaining part 122 of this second reflecting element 12 of this condenser 10 forms one
Individual delustring face 1221, wherein this delustring face 1221 tilt to extend to this reflection of this maintaining part 122 from top to down and upcountry
Room 1220, to reduce the reflected light (and reflected light of non-imaged object) of imaging object as far as possible by this second reflecting element 12
This maintaining part 122 reflects and enters this second reflected light path 120.
It is understood that this delustring face 1221 of this maintaining part 122 of this second reflecting element 12 of this condenser 10
The covering one layer light-absorption layer of light absorbent be made up can be set, or this maintaining part 122 is made up of light absorbent.Art technology
Personnel are appreciated that light absorbent herein refers to have good absorption ability or weak anti-to having light to visible ray
Penetrate the material of ability, such as black material.Preferably, this delustring face 1221 of this maintaining part 122 of this condenser 10 be one overflow
Reflecting curved surface.
As shown in Fig. 2 to Fig. 5 of accompanying drawing, this maintaining part 122 of this second reflecting element 12 of this condenser 10 is further
Form first shading surface 1222, wherein this first shading surface 1222 is set around this reflection room 1220 and can stop into
Reflected light as object enters this reflection room 1220 from this first shading surface 1222 ecto-entad.In other words, this first screening
Bright finish 1222 is set the second reflection that can reduce or even stop this light outside condenser 10 without this optically focused body 11
Face 102 be reflected into this second reflected light path 120.
As shown in Fig. 2 to Fig. 5 of accompanying drawing, this second reflecting element 12 of this condenser 10 further includes one first screening
Photosphere 123 is arranged on this first shading surface 1222 of this maintaining part 122 of this second reflecting element 12, is even stoped with reducing
The light of the outside of this condenser 10 is reflected into this second reflected light path without the second reflecting surface 102 of this optically focused body 11
120.It will be understood by those skilled in the art that this first light shield layer 123 herein is made up of light-proof material.
Shown in Fig. 7 A of accompanying drawing and Fig. 7 B, according to this condenser of this optical imaging device of this utility model preferred embodiment
The further one second reflection body 1211 of this reflecting part 121 of 10 this second reflecting element 12 and second reflecting layer
1212, wherein this second reflection body 1211 has an outer surface 12110, wherein this second reflection body 1211 this second
Reflecting layer 1212 is arranged on this outer surface 12110 of this second reflection body 1211 of this second reflecting element 12, and is formed
This second reflecting surface 102 of this second reflecting element 12.Preferably, this second reflecting layer 1212 is by having good light reflection efficiency
Metal material, such as aluminum, silver-colored or golden etc. make, to improve this second reflecting surface of this second reflecting element 12 of this condenser 10
102 light reflection efficiency.It is highly preferred that this second reflecting layer 1212 is the coat of metal with good oxidation resistance, such as electricity
Aluminium coated.Alternatively, this second reflecting layer 1212 of this second reflecting element 12 of this condenser 10 be sprayed-on being arranged on this
This outer surface 12110 of this second reflection body 1211 of two reflecting elements 12.Alternatively, this second reflecting layer 1212 is capped
This outer surface 12110 in this second reflection body 1211 of this second reflecting element 12.Alternatively, this second reflecting layer 1212
Can be made up of the nonmetallic materials with good light reflection efficiency.It will be understood by those skilled in the art that working as this second reflecting layer
During this outer surface 12110 of this second reflection body 1211 that 1212 are arranged on this second reflecting element 12, this second reflection
Layer 1212 can reduce or even stop the light of this second reflecting layer 1212 top pass through this second reflecting surface 102 and be refracted into
Enter this sensitizing chamber 1100 of this first reflecting element 11 formation, and this optical pickocff 20 being arranged in this sensitizing chamber 1100
Sensing.
As shown in Fig. 1 and 2 of accompanying drawing, this condenser 10 of this optical imaging device further includes a cover body 13, its
In this cover body 13 be arranged between this first reflecting element 11 and this second reflecting element 12, wherein this cover body 13 allow imaging
The reflected light of object passes through this cover body 13 and this first reflecting surface 101 being mapped to condenser 10 after being refracted.Preferably, this cover body
10 can be by glass, and the transparent material such as crystal is made it is also possible to be made up of the light transmissive material that other has good light transmittance.More excellent
Selection of land, this optically focused body 11 is made up of the high light transmissive material that light transmittance is not less than 80%, such as Merlon (PC), polymethyl
Sour formicester (PMMA), high transparent glass material, polyolefin, nylon or crystal etc., the reflected light in order to imaging object is passed through to be somebody's turn to do
Cover body 10 and the first reflecting surface 101 being mapped to condenser 10.Most preferably, the horizontal profile of this cover body 13 of this condenser 10 is in
Centrosymmetry.
It should be noted that this cover body 13 of this condenser 10 of this optical imaging device be sealingly disposed in respectively this
One reflecting element 11 and this second reflecting element 12, therefore, this first reflecting element 11, this second reflecting element 12 and this cover body
13 one optically focused room 100 of formation, wherein when this sensitizing chamber 1100 that this first reflecting element 11 is formed is sealed, this this optically focused
Room 100 is also sealed, so that this optically focused room 100 by sealing and can be charged noble gases or be kept vacuum, in case
Stop this first reflecting layer 112 of this condenser 10 and this second reflecting layer 1212 is aoxidized and improve making of this condenser 10 by too fast
Use the life-span.Preferably, this first reflected light path 110 and the second reflected light path 120 are arranged on this optically focused room 100.
Alternatively, this cover body 13 of this condenser 10 of this optical imaging device is arranged on this first reflecting element 11 He
Between this second reflecting element 12, and mutually it is integrally formed with this first reflecting element 11 and this second reflecting element 12 respectively, with
So that this optically focused room 100 that this first reflecting element 11, this second reflecting element 12 and this cover body 13 are formed can be kept and outside
Air is isolated so that this optically focused room 100 can be charged noble gases or be kept vacuum, with prevent from being arranged on this first
This first reflecting layer 112 of this first reflection body 111 of reflecting element 11 is aoxidized and improves making of this condenser 10 by too fast
Use the life-span.
As shown in Fig. 1 and 2 of accompanying drawing, this cover body 13 of this condenser 10 of this optical imaging device include one high-end
131 and a low side 132, wherein this low side 132 high-end 131 downwardly and inwardly tilts to extend from this, so that just to this cover body
The reflected light of 13 imaging object of this low side 132 can be passed through this low side 132 of this cover body 13 and be mapped to this first reflector
This first reflecting surface 101 of part 11.Preferably, the angle α between this low side 132 and horizontal plane of this cover body 13 is not more than 60 degree.
As shown in Fig. 7 A and 7B of accompanying drawing, the projection radius of this first reflecting surface 101 of this first reflecting element 11 is R1,
The projection radius of this second reflecting surface 102 is R2, the preset vertical between this first reflecting surface 101 and this second reflecting surface 102
Distance is H1, and the wherein projection radius R1 of this first reflecting surface 101 is more than the projection radius R2 of this second reflecting surface 102.Preferably
Ground, after the reflected light of this imaging object is reflected by this first reflecting surface 110, by the reflection of this second reflecting surface 102 secondary reflection again
Angle is β, then angle beta should meet R3/H1 tan β (R3+R2)/H1.Preferably, to be not less than this apart from H1 first anti-for this preset vertical
Penetrate the projection radius R1 in face 101.It is highly preferred that curvature C1 of each several part of this first reflecting surface 101 keeps constant.
As shown in Fig. 2 to Fig. 7 of accompanying drawing, the radius of the light entrance 1101 of this sensitizing chamber 1100 of this first reflecting element 11
For R3.Most preferably, the radius R3 of this light entrance 1101 is less than the projection radius R2 of this second reflecting surface 102.
As shown in Fig. 2 and Fig. 5 of accompanying drawing, according to this condenser of this optical imaging device of this utility model preferred embodiment
10 this first reflecting element 11 further includes a supporting part 113, this first reflection body of this first reflecting element 11
111 have a periphery 1111, and wherein this supporting part 113 is from this periphery 1111 of this first reflecting element 11 outwardly and downwardly
Extend, this first reflection body 111 of this first reflecting element 11 is supported on an appropriate location, and makes this first reflection
This first reflecting surface 101 of element 11 is kept this second reflecting surface 102 towards this second reflecting element 12.
As shown in Fig. 2 and Fig. 5 of accompanying drawing, according to this condenser of this optical imaging device of this utility model preferred embodiment
This high-end 131 this maintaining part 122 being arranged on this second reflecting element 12 from this condenser 10 of 10 this cover body 13, should
This low side 132 of cover body 13 is arranged on this supporting part 113 of this first reflecting element 11.In other words, this cover body 13 extends
Between this maintaining part 122 of this second reflecting element 12 and this supporting part 113 of this first reflecting element 11.
As shown in Fig. 1, Fig. 2, Fig. 5 and Fig. 6 of accompanying drawing, this cover body 13 of this condenser 10 forms a plane of incidence further
104, wherein this plane of incidence 104 is set and continuously extends around this axis 103 of this condenser 10, so that this condenser
10 have a wide-angle visual angle, so that this condenser 10 has a wide-angle visual angle, look around for even 360 degree and regard
Angle, so that this condenser 10 can make the reflected light of all imaging objects in the range of larger angle all can be by this condenser 10
This cover body 13 reflects, and the reflection by this first reflecting surface 101 and this second reflecting surface 102, enters this first reflected light path
110 and this second reflected light path 120 and being accumulated, so that all imaging things in the polarizers of big angle scope of this condenser 10
The reflected light of body all can be sensed by single optical pickocff 20.In other words, make in the range of the larger angle of this condenser 10
The reflected light of all imaging objects all can be reflected by this cover body 13 of this condenser 10, and by this first reflecting surface 101 and is somebody's turn to do
The reflection of the second reflecting surface 102, enters this first reflected light path 110 and this second reflected light path 120 and is accumulated, so that
The reflected light of all imaging objects in the polarizers of big angle scope of this condenser 10 all can be sensed by single optical pickocff 20.
In other words, this cover body 13 of this condenser 10 is set the anti-of the imaging object in the polarizers of big angle scope allowing this condenser 10
Penetrate light to be reflected by this cover body 13 of this condenser 10 so that the reflected light of imaging object can be incident upon this condenser 10 first anti-
Penetrate face 101 and reflected to enter this first reflected light path 110 by this first reflecting surface 101.It will be appreciated by those skilled in the art that
The reflected light of not all imaging object all can enter this first reflected light path after being reflected by this first reflecting surface 101
110.
As shown in Fig. 1, Fig. 2, Fig. 5 and Fig. 6 of accompanying drawing, this cover body 13 of this condenser 10 of this optical imaging device should
The plane of incidence 104 has a high end 1041 and an end portion 1042 extending downwardly from this high end 1041, wherein this cover
This high end 1041 of this high-end 131 this plane of incidence 104 of formation of body 13, this low side 132 of this cover body 13 forms this plane of incidence
This end portion 1042 of 104 this end portion 1042, wherein this plane of incidence 104 of this cover body 13 is from this height of this plane of incidence 104
End 1041 downwardly and inwardly tilts to extend, so that just anti-to the imaging object of this end portion 1042 of this plane of incidence 104
Penetrate light and can pass through this low side 131 of this cover body 13 and this first reflecting surface 101 being mapped to this first reflecting element 11.Preferably
Ground, the angle [alpha] between this end portion 1042 and horizontal plane of this plane of incidence 104 is not more than 60 degree.It is highly preferred that this condenser 10
This plane of incidence 104 horizontal profile centrosymmetry.Alternatively, this end portion 1042 of this plane of incidence 104 is an arc song
Face.
Fig. 8 A and 8B of accompanying drawing show this condenser of this optical imaging device according to this utility model preferred embodiment
This second reflecting element 12A of the optional enforcement of one kind of 10 this second reflecting element 12, wherein this condenser 10 includes one
Reflecting part 121A and maintaining part 122A, wherein this reflecting part 121A form this second reflecting surface 102, this maintaining part 122A shape
Become a delustring face 1221A, wherein this delustring face 1221A upward and outward tilts to extend from this second reflecting surface 102, with to the greatest extent
The reflected light being likely to reduced or even stoping imaging object should by this maintaining part 122A reflection of this second reflecting element 12A and entrance
Second reflected light path 120.Preferably, this delustring face 1221A that this maintaining part 122A of this condenser 10 is formed is one and overflows instead
Penetrate curved surface.
Shown in Fig. 7 A of accompanying drawing and Fig. 7 B, according to this condenser of this optical imaging device of this utility model preferred embodiment
The further one second reflection body 1211A of this reflecting part 121A of 10 this second reflecting element 12A and one second reflection
Layer 1212A, wherein this second reflection body 1211A has an outer surface 12110A, wherein this second reflection body 1211A
This second reflecting layer 1212A is arranged on this outer surface of this second reflection body 1211A of this second reflecting element 12A
12110A, and form this second reflecting surface 102 of this second reflecting element 12A, wherein this delustring face 1221A is from this second reflection
Face 102 upward and outward tilts to extend.Preferably, this second reflecting layer 1212A is by the metal with good light reflection efficiency
Material, such as aluminum, silver-colored or golden etc. make, to improve this second reflecting surface 102 of this second reflecting element 12A of this condenser 10
Light reflection efficiency.It is highly preferred that this second reflecting layer 1212A is the coat of metal with good oxidation resistance, such as Electroplating Aluminum
Layer.Alternatively, this second reflecting layer 1212A of this second reflecting element 12A of this condenser 10 be sprayed-on being arranged on this second
This outer surface 12110A of this second reflection body 1211A of reflecting element 12A.Alternatively, this second reflecting layer 1212A is coated to
Cover this outer surface 12110A of this second reflection body 1211A in this second reflecting element 12A.Alternatively, this second reflection
Layer 1212A is made up of the nonmetallic materials with good light reflection efficiency.It will be understood by those skilled in the art that it is second anti-when this
When penetrating this outer surface 12110A of this second reflection body 1211A that layer 1212A is arranged on this second reflecting element 12A, should
Second reflecting layer 1212A can reduce or even stop the light above this second reflecting layer from passing through this second reflecting surface 102 and quilt
It is refracted into this second reflected light path 120, and this optical pickocff 20 being arranged in this sensitizing chamber 1100 senses.
It is understood that this delustring face 1221 of this maintaining part 122 of this second reflecting element 12 of this condenser 10
The covering one layer light-absorption layer of light absorbent be made up can be set, or this maintaining part 122 is made up of light absorbent.Art technology
Personnel are appreciated that light absorbent herein refers to have good absorption ability or weak anti-to having light to visible ray
Penetrate the material of ability, such as black material.Preferably, this delustring face 1221 of this maintaining part 122 of this condenser 10 be one overflow
Reflecting curved surface.
It will be understood by those skilled in the art that preferably, this first reflecting layer 112A, this second reflecting layer 1212A and should
First light shield layer 123 is made by light-proof material.
It will be understood by those skilled in the art that the embodiment of the present utility model shown in foregoing description and accompanying drawing is only used as lifting
Example and be not intended to limit this utility model.
The purpose of this utility model is completely and be effectively realized.Function of the present utility model and structural principle are in reality
Apply and show in example and illustrate, without departing under described principle, embodiment of the present utility model can have and any deform or repair
Change.
Claims (55)
1. a kind of optical imaging device is it is characterised in that include:
One condenser, wherein this condenser have an axis and form an optically focused light path, wherein the regarding of this condenser
Angle is set and is formed around this axis, so that this condenser is set the imaging object that can converge this condenser angular field of view
Reflected light to this optically focused light path;
One optical pickocff, wherein this optical pickocff are arranged on this optically focused light path, and wherein this optical pickocff is set
The reflected light being accumulated to this optically focused light path and the corresponding light sensation induction signal of generation can be sensed;With
One signal processing module, wherein this signal processing module can be connected with this optical pickocff with being energized, wherein this letter
Number processing module is set this light sensation induction signal that can receive the generation of this optical pickocff.
2. optical imaging device according to claim 1 it is characterised in that this condenser formed first reflecting surface and
One the second reflecting surface, wherein this first reflecting surface and the second reflecting surface are separated by be arranged with turning up the soil and practise physiognomy opposite, wherein should
First reflecting surface and this second reflecting surface form first reflected light path and second reflected light path, wherein this first reflection
Light path is formed between this first reflecting surface and this second reflecting surface, and this second reflected light path is formed at this first reflected light path
Inner side, wherein this first reflecting surface are set and the reflected light back of imaging object can be entered this first reflected light path, and
The reflected light of imaging object is entered after this first reflected light path by this first reflective surface, and the reflected light of imaging object can be by
This second reflecting surface secondary reflection and this second reflected light path of entrance again, wherein this second reflected light path forms this optically focused light path.
3. optical imaging device according to claim 2 is it is characterised in that this condenser includes first reflecting element
It is separated by with second reflecting element, wherein this first reflecting element and this second reflecting element and set with turning up the soil and practise physiognomy opposite
Put, wherein this first reflecting element forms this first reflecting surface, this second reflecting element forms this second reflecting surface, is wherein imaged
The reflected light of object is entered after this first reflected light path by this first reflective surface of this first reflecting element, this imaging object
This reflected light can by this second reflecting surface of this second reflecting element again secondary reflection and enter this second reflected light path, wherein
This second reflected light path forms this optically focused light path.
4. optical imaging device according to claim 2 is it is characterised in that this condenser includes first reflecting element
It is separated by with second reflecting element, wherein this first reflecting element and this second reflecting element and set with turning up the soil and practise physiognomy opposite
Put, wherein this first reflecting element forms this first reflecting surface, this second reflecting element forms this second reflecting surface.
5. optical imaging device according to claim 2 is it is characterised in that this first reflecting surface of this condenser is set
Put that the reflected light of the imaging object in the angular field of view of this condenser can be reflected into synchronously and in the same manner this is first anti-
Penetrate light path.
6. optical imaging device according to claim 4 is it is characterised in that this first reflecting surface of this condenser is set
The reflected light of the imaging object in the angular field of view of this condenser can be reflected into synchronously and in the same manner this first reflection
Light path.
7. optical imaging device according to claim 2 is it is characterised in that this first reflecting surface is a convex refractive
Face, this second reflecting surface is a plane reflection face.
8. optical imaging device according to claim 6 is it is characterised in that this first reflecting surface is a convex refractive
Face, this second reflecting surface is a plane reflection face.
9. optical imaging device according to claim 2 is it is characterised in that this first reflecting element of this condenser is formed
One sensitizing chamber being connected with this optically focused light path, wherein this optically focused light path in this photosensitive interior formation one sensing light path, its
In this optical pickocff be arranged on this sensing light path so that this optical pickocff be arranged on being hidden this first reflection
This sensitizing chamber of element.
10. optical imaging device according to claim 8 is it is characterised in that this first reflecting element shape of this condenser
Become a sensitizing chamber being connected with this optically focused light path, wherein this optically focused light path in this photosensitive one sensing light path of interior formation,
Wherein this optical pickocff is arranged on this sensing light path so that this optical pickocff be arranged on this with being hidden first anti-
Penetrate this sensitizing chamber of element.
11. optical imaging devices according to claim 2 it is characterised in that this first reflecting surface projection radius be R1,
The projection radius of this second reflecting surface is R2, and the wherein projection radius R1 of this first reflecting surface is more than the projection of this second reflecting surface
Radius R2.
12. optical imaging devices according to claim 10 are it is characterised in that the projection radius of this first reflecting surface is
R1, the projection radius of this second reflecting surface is R2, and the wherein projection radius R1 of this first reflecting surface is more than this second reflecting surface
Projection radius R2.
13. optical imaging devices according to claim 2 it is characterised in that this first reflecting surface from top to down and to
Other places is continuous to be extended, to form a continuous convex surface.
14. optical imaging devices according to claim 12 it is characterised in that this first reflecting surface from top to down and to
Other places is continuous to be extended, to form a continuous convex surface.
15. optical imaging devices according to claim 3 are it is characterised in that this first reflecting element of this condenser enters
One step includes one first reflection body and first reflecting layer, and wherein this first reflection body has a lateral surface, its
In this first reflection body this first reflecting layer be arranged on this first reflecting element this first reflection body this outside
Face, and form this first reflecting surface of this condenser.
16. optical imaging devices according to claim 14 are it is characterised in that this first reflecting element of this condenser enters
One step includes one first reflection body and first reflecting layer, and wherein this first reflection body has a lateral surface, its
In this first reflection body this first reflecting layer be arranged on this first reflecting element this first reflection body this outside
Face, and form this first reflecting surface of this condenser.
17. optical imaging devices according to claim 15 are it is characterised in that this first reflecting layer of this condenser is plating
Electroplating aluminum coating in this lateral surface of this first reflection body of this first reflecting element.
18. optical imaging devices according to claim 16 are it is characterised in that this first reflecting layer of this condenser is plating
Electroplating aluminum coating in this lateral surface of this first reflection body of this first reflecting element.
19. optical imaging devices according to claim 3 are it is characterised in that this second reflecting element of this condenser enters
One step includes a reflecting part and a maintaining part, and wherein this maintaining part is from this reflecting part of this second reflecting element to extension
Stretch, wherein this reflecting part forms this second reflecting surface, this maintaining part forms a reflection room and a delustring face, wherein this second
This reflecting part of reflecting element is arranged on this reflection room, and this delustring faces down and upcountry tilts to extend to being somebody's turn to do of this maintaining part
Reflection room.
20. optical imaging devices according to claim 18 are it is characterised in that this second reflecting element of this condenser enters
One step includes a reflecting part and a maintaining part, and wherein this maintaining part is from this reflecting part of this second reflecting element to extension
Stretch, wherein this reflecting part forms this second reflecting surface, this maintaining part forms a reflection room and a delustring face, wherein this second
This reflecting part of reflecting element is arranged on this reflection room, and this delustring faces down and upcountry tilts to extend to being somebody's turn to do of this maintaining part
Reflection room.
21. optical imaging devices according to claim 3 it is characterised in that this condenser further includes a cover body,
Wherein this cover body is arranged between this first reflecting element and this second reflecting element, and wherein this cover body allows imaging object
Reflected light passes through this cover body and this first reflecting surface being mapped to condenser after being refracted by this cover body.
22. optical imaging devices according to claim 20 are it is characterised in that this condenser further includes a cover
Body, wherein this cover body are arranged between this first reflecting element and this second reflecting element, and wherein this cover body allows imaging thing
The reflected light of body passes through this cover body and this first reflecting surface being mapped to condenser after being refracted by this cover body.
23. optical imaging devices according to claim 3 it is characterised in that this condenser further includes a cover body,
Wherein this cover body is arranged between this first reflecting element and this second reflecting element, wherein this cover body include one high-end and
One low side, wherein this low side extend from this high-end downwardly and inwardly inclination.
24. optical imaging devices according to claim 22 it is characterised in that this cover body include one high-end and one low
End, wherein this low side extend from this high-end downwardly and inwardly inclination.
To be located at this first anti-it is characterised in that this cover body forms one for 25. optical imaging devices according to claim 21
Penetrate the optically focused room between element and this second reflecting element, wherein this cover body be sealingly disposed in respectively this first reflecting element and
This second reflecting element, wherein this first reflected light path and the second reflected light path are arranged on this optically focused room, and this optically focused room quilt
Setting can be charged noble gases or be kept vacuum.
To be located at this first anti-it is characterised in that this cover body forms one for 26. optical imaging devices according to claim 24
Penetrate the optically focused room between element and this second reflecting element, wherein this cover body be sealingly disposed in respectively this first reflecting element and
This second reflecting element, wherein this first reflected light path and the second reflected light path are arranged on this optically focused room, wherein this optically focused room
It is set and can be charged noble gases or be kept vacuum.
27. optical imaging devices according to claim 23 are it is characterised in that this cover body forms an incidence further
One high end of this high-end this plane of incidence of formation in face, wherein this cover body, this low side of this cover body forms the low of this plane of incidence
End.
28. optical imaging devices according to claim 26 are it is characterised in that this cover body forms an incidence further
One high end of this high-end this plane of incidence of formation in face, wherein this cover body, this low side of this cover body forms the low of this plane of incidence
End.
29. optical imaging devices according to claim 2 it is characterised in that this first reflecting surface projection radius be R1,
The projection radius of this second reflecting surface is R2, and the wherein projection radius R1 of this first reflecting surface is more than the projection of this second reflecting surface
Radius R2.
A kind of 30. condensers, it is characterised in that this condenser has an axis and forms an optically focused light path, wherein should
The visual angle of condenser is set and is formed around this axis, so that this condenser is set can converge this condenser angular field of view
Imaging object reflected light to this optically focused light path, wherein this condenser forms first reflecting surface and one second reflection
Face, wherein this first reflecting surface and the second reflecting surface are separated by be arranged with turning up the soil and practise physiognomy opposite, wherein this first reflecting surface and
This second reflecting surface forms first reflected light path and second reflected light path, and wherein this first reflected light path is formed at this
Between first reflecting surface and this second reflecting surface, this second reflected light path is formed at the inner side of this first reflected light path, wherein should
The reflected light back of imaging object can be entered this first reflected light path, and the reflected light quilt in imaging object by the first reflecting surface
After this first reflective surface enters this first reflected light path, the reflected light of imaging object can be anti-again by this second reflecting surface
Penetrate and enter this second reflected light path.
31. condensers according to claim 30 it is characterised in that this condenser include first reflecting element and
One the second reflecting element, wherein this first reflecting element and this second reflecting element are separated by be set with turning up the soil and practise physiognomy opposite
Put, wherein this first reflecting element forms this first reflecting surface, this second reflecting element forms this second reflecting surface, is wherein imaged
The reflected light of object is entered after this first reflected light path by this first reflective surface of this first reflecting element, this imaging object
This reflected light can by this second reflecting surface of this second reflecting element again secondary reflection and enter this second reflected light path.
32. condensers according to claim 30 it is characterised in that this first reflecting surface of this condenser be set can
The reflected light of the imaging object in the angular field of view of this condenser is reflected into synchronously and in the same manner this first reflected light path.
33. condensers according to claim 31 it is characterised in that this first reflecting surface of this condenser be set can
The reflected light of the imaging object in the angular field of view of this condenser is reflected into synchronously and in the same manner this first reflected light path.
34. condensers according to claim 30, should it is characterised in that this first reflecting surface is convex curved reflecting surfaces
Second reflecting surface is a plane reflection face.
35. condensers according to claim 33, should it is characterised in that this first reflecting surface is convex curved reflecting surfaces
Second reflecting surface is a plane reflection face.
36. condensers according to claim 30 are it is characterised in that this first reflecting element of this condenser forms one
The sensitizing chamber being connected with this second reflected light path, wherein this second reflected light path are in this photosensitive one sensing light of interior formation
Road.
37. condensers according to claim 35 are it is characterised in that this first reflecting element of this condenser forms one
The sensitizing chamber being connected with this second reflected light path, wherein this second reflected light path are in this photosensitive one sensing light of interior formation
Road.
, it is characterised in that the projection radius of this first reflecting surface is R1, this for 38. condensers according to claim 30
The projection radius of two reflectings surface is R2, and the wherein projection radius R1 of this first reflecting surface is more than the projection radius of this second reflecting surface
R2.
, it is characterised in that the projection radius of this first reflecting surface is R1, this for 39. condensers according to claim 37
The projection radius of two reflectings surface is R2, and the wherein projection radius R1 of this first reflecting surface is more than the projection radius of this second reflecting surface
R2.
40. condensers according to claim 30 are it is characterised in that this first reflecting surface connects from top to down and outwards
Renew and stretch, to form a continuous convex surface.
41. condensers according to claim 39 it is characterised in that this first reflecting surface from top to down and outwards
Continuous extension, to form a continuous convex surface.
42. condensers according to claim 31 are it is characterised in that this first reflecting element of this condenser wraps further
Include one first reflection body and first reflecting layer, wherein this first reflection body has a lateral surface, wherein this
This first reflecting layer of one reflection body is arranged on this lateral surface of this first reflection body of this first reflecting element, and shape
Become this first reflecting surface of this condenser.
43. condensers according to claim 41 are it is characterised in that this first reflecting element of this condenser wraps further
Include one first reflection body and first reflecting layer, wherein this first reflection body has a lateral surface, wherein this
This first reflecting layer of one reflection body is arranged on this lateral surface of this first reflection body of this first reflecting element, and shape
Become this first reflecting surface of this condenser.
44. condensers according to claim 42 it is characterised in that this first reflecting layer of this condenser be plated in this
The electroplating aluminum coating of this lateral surface of this first reflection body of one reflecting element.
45. condensers according to claim 43 it is characterised in that this first reflecting layer of this condenser be plated in this
The electroplating aluminum coating of this lateral surface of this first reflection body of one reflecting element.
46. condensers according to claim 31 are it is characterised in that this second reflecting element of this condenser wraps further
Include a reflecting part and a maintaining part, wherein this maintaining part stretches out from this reflecting part of this second reflecting element, wherein
This reflecting part forms this second reflecting surface, and this maintaining part forms a reflection room and a delustring face, wherein this second reflector
This reflecting part of part is arranged on this reflection room, and this delustring face tilts to extend to being somebody's turn to do of this maintaining part from top to down and upcountry
Reflection room.
47. condensers according to claim 45 are it is characterised in that this second reflecting element of this condenser wraps further
Include a reflecting part and a maintaining part, wherein this maintaining part stretches out from this reflecting part of this second reflecting element, wherein
This reflecting part forms this second reflecting surface, and this maintaining part forms a reflection room and a delustring face, wherein this second reflector
This reflecting part of part is arranged on this reflection room, and this delustring face tilts to extend to being somebody's turn to do of this maintaining part from top to down and upcountry
Reflection room.
48. condensers according to claim 31 are it is characterised in that this condenser further includes a cover body, wherein
This cover body is arranged between this first reflecting element and this second reflecting element, and wherein this cover body allows the reflection of imaging object
Light passes through this cover body and this first reflecting surface being mapped to condenser after being refracted by this cover body.
49. condensers according to claim 47 are it is characterised in that this condenser further includes a cover body, wherein
This cover body is arranged between this first reflecting element and this second reflecting element, and wherein this cover body allows the reflection of imaging object
Light passes through this cover body and this first reflecting surface being mapped to condenser after being refracted by this cover body.
50. condensers according to claim 48 it is characterised in that this cover body includes a high-end and low side, its
In this low side from this high-end downwardly and inwardly tilt extend.
51. condensers according to claim 49 it is characterised in that this cover body includes a high-end and low side, its
In this low side from this high-end downwardly and inwardly tilt extend.
52. condensers according to claim 48 are located at this first reflecting element it is characterised in that this cover body forms one
Optically focused room and this second reflecting element between, wherein this cover body be sealingly disposed in respectively this first reflecting element and this second
Reflecting element, wherein this first reflected light path and the second reflected light path are arranged on this optically focused room, and this optically focused room is set energy
Enough it is charged noble gases or be kept vacuum.
53. condensers according to claim 51 are located at this first reflecting element it is characterised in that this cover body forms one
Optically focused room and this second reflecting element between, wherein this cover body be sealingly disposed in respectively this first reflecting element and this second
Reflecting element, wherein this first reflected light path and the second reflected light path are arranged on this optically focused room, and wherein this optically focused room is set
Noble gases can be charged or be kept vacuum.
54. condensers according to claim 50 are it is characterised in that this cover body forms a plane of incidence further, wherein
One high end of this high-end this plane of incidence of formation of this cover body, this low side of this cover body forms the end portion of this plane of incidence.
55. condensers according to claim 53 are it is characterised in that this cover body forms a plane of incidence further, wherein
One high end of this high-end this plane of incidence of formation of this cover body, this low side of this cover body forms the end portion of this plane of incidence.
Priority Applications (2)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN201521031140.1U CN205958833U (en) | 2015-12-11 | 2015-12-11 | Optical imaging device and spotlight ware thereof |
| PCT/CN2016/109416 WO2017097263A1 (en) | 2015-12-11 | 2016-12-12 | Optical imaging apparatus, condenser thereof, and application thereof |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN201521031140.1U CN205958833U (en) | 2015-12-11 | 2015-12-11 | Optical imaging device and spotlight ware thereof |
Publications (1)
| Publication Number | Publication Date |
|---|---|
| CN205958833U true CN205958833U (en) | 2017-02-15 |
Family
ID=57966358
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CN201521031140.1U Expired - Fee Related CN205958833U (en) | 2015-12-11 | 2015-12-11 | Optical imaging device and spotlight ware thereof |
Country Status (1)
| Country | Link |
|---|---|
| CN (1) | CN205958833U (en) |
Cited By (2)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN105425374A (en) * | 2015-12-11 | 2016-03-23 | 宁波舜宇光电信息有限公司 | Optical imaging device and condenser |
| CN109713108A (en) * | 2018-12-30 | 2019-05-03 | 苏州东大科云硬件科技有限公司 | A kind of packaging method of light emitting diode |
-
2015
- 2015-12-11 CN CN201521031140.1U patent/CN205958833U/en not_active Expired - Fee Related
Cited By (4)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN105425374A (en) * | 2015-12-11 | 2016-03-23 | 宁波舜宇光电信息有限公司 | Optical imaging device and condenser |
| CN105425374B (en) * | 2015-12-11 | 2018-10-30 | 宁波舜宇光电信息有限公司 | Optical imaging device and its concentrator |
| CN109713108A (en) * | 2018-12-30 | 2019-05-03 | 苏州东大科云硬件科技有限公司 | A kind of packaging method of light emitting diode |
| CN109713108B (en) * | 2018-12-30 | 2020-11-10 | 苏州东大科云硬件科技有限公司 | Packaging method of light emitting diode |
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